Two coherent sources `S_(f)` and `S_(2)` (in phase with ech other) are placed at a distance of `2lambda` as shown where `lambda` is wavelength of sound. A detector moves on line `A B` parrallel to `S_(1)S_(2)`. If detector detects maximum intensity at finite distance from `O` at `theta = +- ((pi)/(n))`. Find `n`

Two coherent sources S_(1)" and "S_(2) are separated by a small distance d. The fringes obtained on the screen will be:

Two coherent point sources S_1 and S_2 are separated by a small distance d as shown. The fringes obtained on the screen will be

Two coherent point sources S_1 and S_2 are separated by a small distance d as shown. The fringes obtained on the screen will be

Two coherent light sources S_1 and S_2 (lambda=6000Å) are 1mm apart from each other. The screen is placed at a distance of 25cm from the sources. The width of the fringes on the screen should be

Two source of sound, S_(1) and S_(2) , emitting waves of equal wavelength 2 cm , are placed with a separation of 3 cm between them. A detector can be moved on a line parallel to S_(1) S_(2) and at a distance 24 cm from it. Initially, the detecor is equidistant from the two sources. Assuming that the waves emitted by the sources are in phase, find the minimum distance through which the detector should be shifted to detect a minimum of sound.

Two coherent point sources S_(1) and S_(2) vibrating in phase emit light of wavelength lambda . The separation between the sources is 2lambda . Consider a line passing through S_(2) and perpendicular to line S_(1) S_(2) . Find the position of farthest and nearest minima. .

Two coherent point sources S_1 " and "S_2 vibrating in phase light of wavelength lambda . The separation between the sources is 2lambda . The smallest distance from S_(2) on a line passing through S_2 and perpendicular to s_(1)s_(2) where a minimum of intensity occurs is

Two monochromatic coherent point sources S_(1) and S_(2) are separated by a distance L. Each sources emits light of wavelength lambda , where L gt gt lambda . The line S_(1) S_(2) when extended meets a screen perpendicular to it at point A. Then

S_(1)S_(2) are two coherent cources (having initial phase difference zero) of sound located along x -axis separated by 4 lambda where lambda is wavelength of sound emitted by them. Number of maxima located on the ellopical boundry around it will be.

two speakers A and B , placed 1 m apart, each produces sound waves of frequnecy 1800 Hz. In phase. A detector moving parallel to line of speakers distant 2.4 m away detects a maximum intensity at O nd then at P. speed of sound wave is